Deliverables, Highlights, and Reports. status and plans news and one-pagers annual and exit reports points of emphasis

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1 Deliverables, Highlights, and Reports status and plans news and one-pagers annual and exit reports points of emphasis

2 Year-5 Deliverables (from Year-4 annual report summary) Ab-initio Deliverables (Monday) Further calculate homogeneous neutron matter and neutron drops in external fields using GFMC and AFDMC to create pseudo-data for constraining energy density functionals. Calculate the Hoyle state with GFMC. Continue improvements to ADLB resulting in community usable code. The LCCI project will deliver final UNEDF versions of LCCI codes, scripts, and test cases and the prototype DBMS will be completed and released. Study role of NNN forces in medium mass nuclei with CC. Analyze LQCD calculations of multi-baryon systems at sufficiently low pion mass to permit extrapolation to the physical point. Complete CUDA hybrid Monte Carlo (HMC) codes and apply them to the first large-scale HMC calculations of the unitary Fermi gas.

3 Year-5 Deliverables (from Year-4 annual report summary) Ab initio Functionals Deliverables (Tuesday/Wednesday) Perform neutron drop benchmarks starting from realistic NN and NNN interactions and validate against ab-initio calculations. Develop the Optimized Effective Potential method for 3D-HFB; compare with HF, HF-DME, and ab initio. Develop improved DME functionals that go beyond Hartree-Fock. Use in-medium SRG to develop valence shell model Hamiltonians and effective operators for open-shell nuclei.

4 Year-5 Deliverables (from Year-4 annual report summary) DFT Infrastructure/Applications Deliverables (Tues./Wed.) Full implementation of ADIOS in HFODD; set up framework for automatic restart. Optimize generalized Skyrme functionals and DME functionals by considering additional constraints on states at large deformation, shell structure, giant resonances, and neutron droplets pseudo-data from ab-initio calculations. Use UNEDF functionals in large-scale surveys, spectroscopy, and description of fission. Develop open-source implementation of POUNDERS. Continue development of model-based optimization algorithms for noisy and constrained calculations. Global explorations of the parameter space by means of a space-filling design in order to delineate regions of stability of EDF. Further optimize the ASLDA DFT solver. Implement the constrained 3D Skyrme-HFB-MADNESS framework and apply to fission and cold fermions.

5 Year-5 Deliverables (from Year-4 annual report summary) DFT Extensions Deliverables (Wednesday) Use the new QRPAdef code to complete the beta decay calculation Develop DFT-consistent code beyond QRPA Use the TDSLDA code to describe collective motion in nuclei Develop and test the J-Moments nuclear level density code that removes the center- of-mass spurious states Use the new J-Moments code to calculate reaction rates in the rp-process path Understand the scalability barriers in NuShellX to enable the most effective use of Graphic Processing Units (GPUs) and leadership-class machines. Improve the scalability of BIGSTICK CI code up to 50,000 cores Use BIGSTICK code to investigate isospin breaking in pf shell

6 Year-5 Deliverables (from Year-4 annual report summary) Reaction Deliverables (Thursday) Investigate reactions in light nuclei using NCSM with RGM: Benchmark n-8he, and n-9li scattering. Investigate p-7be and 3H+4He scattering and capture reactions. Use two-, three-, and four-body transition densities for A = 3, 4 nuclei. Development of three-body transition density calculation for A > 4. Analyze Ab initio nuclear scattering in HO traps to three and four-body systems such as n-d and n-t. Consistent nucleon-nucleus optical potentials within elastic and all inelastic and transfer channels. Fold QRPA transition densities with density-dependent and spin-orbit forces. Include effective masses, and direct charge-exchange. Calculate and investigate effects of exchange nonlocalities.

7 Year-5 Deliverables (from Year-4 annual report summary) (more) Reaction Deliverables (Thursday) Systematic generation of optical potentials for a wide range of near-spherical nuclei. First nucleon-nucleus calculations with deformed QRPA transition densities. Examine role of optical-potential L-dependences & non-localities in direct reaction calculations. Examine energy-dependence of eigensolutions in the expansion for the KKM theory.

8 Preparation for UNEDF annual and final reports Needed from each section leader Progress reports on Year-5 deliverables Plans for carry-over funds (if any) To me by ASAP Papers acknowledging UNEDF (both published and preprints) ***UNEDF-related invited talks*** (non-collaboration meeting) Check unedf.org for what is missing since Year-4 CPR! UNEDF-related Good News and UNEDF in the News Highlights a new one (or more) from every sub-project! Guidelines for continuation progress report and final report CPR like last year (but less time pressure) Final exit report due June, 2012

9 UNEDF Highlights and News One-page highlights are needed for our sponsors to tell our successes to DOE NP, ASCR, NNSA to give them success stories to tell for DNP and NSAC and... also for broader science community and general public Website unedf.org is repository for highlights and news Status of website going forward? Nuclear Physics News articles on UNEDF physics in June project overview (copies available), NCSM, FUSTIPEN linked on unedf.org

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13 Highlights of research on unedf.org One-slide summaries targeted for broad audience or for specific sponsors Notes with details and references (usually) Also look under Internal One-Pagers

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15 For all UNEDF speakers: Points to emphasize What are the main accomplishments since the last meeting? Is your Year-5 plan well on track? If not, why? What are the aspects of your science that require highperformance computing? OR What problems in high performance computing are you working on in general? What are the major computational issues? Are there any questions you would like to bring to the attention of our CS/AM collaborators? OR Are there general capabilities of your CS/AM work that might be of interest to other physicists than the ones you are currently working with? What is the detailed roadmap of your project for the remaining part of Year-5 (and beyond)? Are there any showcase (i.e., of Nature/Science caliber) physics and computational questions that you are hoping to answer in Year 5?

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